Saturated cyclic amines (aza-cycles) are ubiquitous structural motifs found in pharmaceuticals, agrochemicals, and bioactive natural products. Given their importance, methods that directly functionalize aza-cycles are in high demand. Herein, we disclose a fundamentally different approach to functionalizing cyclic amines which relies on C−C cleavage and attendant cross-coupling. The initial functionalization step is the generation of underexplored N-fused bicyclo α-hydroxy-β-lactams under mild, visible light conditions using a Norrish−Yang process to affect α-functionalization of saturated cyclic amines. This approach is complementary to previous methods for the C−H functionalization of aza-cycles and provides unique access to various cross-coupling adducts. In the course of these studies, we have also uncovered an orthogonal, base-promoted opening of the N-fused bicyclo α-hydroxy-β-lactams. Computational studies have provided insight into the origin of the complementary C−C cleavage processes.
Herein
we report the synthesis of substituted indolizidines and
related N-fused bicycles from simple saturated cyclic amines through
sequential C–H and C–C bond functionalizations. Inspired
by the Norrish–Yang Type II reaction, C–H functionalization
of azacycles is achieved by forming α-hydroxy-β-lactams
from precursor α-ketoamide derivatives under mild, visible light
conditions. Selective cleavage of the distal C(sp2)–C(sp3) bond in α-hydroxy-β-lactams using a Rh-complex
leads to α-acyl intermediates which undergo sequential Rh-catalyzed
decarbonylation, 1,4-addition to an electrophile, and aldol cyclization,
to afford N-fused bicycles including indolizidines. Computational
studies provide mechanistic insight into the observed positional selectivity
of C–C cleavage, which depends strongly on the groups bound
to Rh trans to the phosphine ligand.
The construction of complex aza-cycles is of interest to drug discovery due to the prevalence of nitrogen-containing heterocycles in pharmaceutical agents. Herein we report an intramolecular C−H amination approach to afford value-added and complexity-enriched bridged bicyclic amines. Guided by density functional theory and nuclear magnetic resonance investigations, we determined the unique roles of light and heat activation in the bicyclization mechanism. We applied both light and heat activation in a synergistic fashion, achieving gram-scale bridged aza-cycle synthesis.
Chemical synthesis of natural products is typically inspired by the structure and function of a target molecule. When both factors are of interest, such as in the case of taxane diterpenoids, a synthesis can both serve as a platform for synthetic strategy development and enable new biological exploration. Guided by this paradigm, we present here a unified enantiospecific approach to diverse taxane cores from the feedstock monoterpenoid (S)-carvone. Key to the success of our approach was the use of a skeletal remodeling strategy which began with the divergent reorganization and convergent coupling of two carvonederived fragments, facilitated by Pd-catalyzed C−C bond cleavage tactics. This coupling was followed by additional restructuring using a Sm(II)-mediated rearrangement and a bioinspired, visiblelight induced, transannular [2 + 2] photocycloaddition. Overall, this divergent monoterpenoid remodeling/convergent fragment coupling approach to complex diterpenoid synthesis provides access to structurally disparate taxane cores which have set the stage for the preparation of a wide range of taxanes.
An enantio‐ and stereoselective formal total synthesis of (+)‐frondosin A was accomplished through an oxidopyrylium‐ion‐mediated [5+2] cycloaddition reaction. The cycloaddition reaction provided not only an efficient way of constructing the frondosin skeleton but also facial discrimination through an ether bridge for complete control of relative stereochemistry of the substituents in frondosin A.
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